Spectral and physical characterization of the inverted terminal repeat DNA structure from adenoassociated virus 2

An oligodeoxynucleotide (ODN) that includes elements found in secondary structures at the 5'- and 3'- ends of adenoassociated virus 2 virion DNA was synthesized by ligation of three overlapping ODNs. The most stable secondary structure was calculated to be branched, with a 61 bp duplex stem, terminating in a three-way junction with 9 bp arms. The electrophoretic mobility of the ODN is slower than expected for normal duplex DNA of the same size, suggesting a bent or branched conformation. CD spectra indicate that the ITR structure is largely B form DNA, although there is a slight blue shift compared to the spectra of the isolated stem and loop elements. Thermal melting experiments indicate that the hairpin is significantly more stable than the isolated stem and loop elements. Singular value decomposition of UV spectra obtained as a function of temperature indicates that four species contribute to changes in the spectra upon denaturation, indicating that the melting is not a simple two-state process. Characterization of the branched ODN by differential scanning calorimetry permits estimation of the enthalpy of melting by a model-free analysis, yielding DeltaHcal= 614 kcal mol-1. This value agrees with the enthalpy computed for the most stable secondary structure.     

Thermodynamic properties of an intramolecular DNA four-way junction

We have investigated the thermodynamic properties of two homologous DNA four-way junctions, J4 and J4M, based on 46-mer linear DNA molecules. J4 and J4M have the same base sequence with the only difference that the latter contains an uncharged methylene-acetal linkage, -O3'-CH2-O5', instead of the phosphodiester linkage, -O3'-PO2-O5'-, between the residues T18 and C19. The comparison of the thermal unfolding of the J4 junction and J4M junction serves to investigate the effect of the uncharged methylene-acetal linkage on the stability of the junction. Our analysis is based on CD, UV absorbance spectroscopy, DSC, and chemical footprinting. The aim is to characterize in detail the structure and stability of the junctions. As demonstrated before by NMR, in the presence of 5 mM MgCl2 +/- 50 mM NaCl, both J4 and J4M form a complete four-way junction. This is now evidenced by protection from OsO4 cleavage (chemical footprinting). We can assume that full base pairing occurs throughout the arms even at the center of the junction. CD spectra suggest that the helices within the junctions adopt the regular B-DNA conformation. Almost identical melting temperatures and unfolding enthalpies are obtained for J4 and J4M both by UV and DSC. Furthermore, the Van't Hoff enthalpy (DeltaHVH) derived from UV melting equals the calorimetric enthalpy (DeltaHcal), which means that the melting process of the structures proceeds in a two-state manner. All results taken together support the conclusion that there are no major conformational and energetic differences between J4 and J4M. The inclusion of the uncharged methylene-acetal group into the junction has no effect on its stability.     

Deoxydodecanucleotide heteroduplex d(TTTTATAATAAA). d(TTTATTATAAAA) containing the promoter Pribnow sequence TATAAT. I. Double-helix stability by UV spectrophotometry and calorimetry

Thermally induced structural transition in the d(TTTTATAATAAA) d(TTTATTATAAAA) heteroduplex is characterized by UV-spectroscopy and differential scanning calorimetry. At low salt (less than 0.1 M) the occurrence of a cooperative transition in the lower temperature range, followed by a broad transition connected with small increase in absorbance is observed. At high salt (greater than or equal to 0.2 M) a single, monophasic transition appears. Linear dependence of the latter on log of salt concentration (dTm:dlogM = 14.2 degrees C) and of 1/Tm on log of oligomer concentration [derived therefrom delta H (v.H.) = 77.1 kcal/mole (duplex)] allows relating it to the melting of the heteroduplex helix. The non-cooperative transition, independent of oligomer concentration and similar to that of the single chain, was attributed to melting of short hairpin helices upon heteroduplex dissociation. Calorimetric enthalpy: 75.6 kcal/mole (duplex) proved significantly lower than predicted from known calorimetric data for poly[d(AT)] and poly d(A) X poly d(T).     

UV resonance Raman and circular dichroism studies of a DNA duplex containing an A(3)T(3) tract: evidence for a premelting transition and three-centered H-bonds.

The presence of A(n) and A(n)T(n) tracts in double-helical sequences perturbs the structural properties of DNA molecules, resulting in the formation of an alternate conformation to standard B-DNA known as B'-DNA. Evidence for a transition occurring prior to duplex melting in molecules containing A(n) tracts was previously detected by circular dichroism (CD) and calorimetric studies. This premelting transition was attributed to a conformational change from B'- to B-DNA. Structural features of A(n) and A(n)T(n) tracts revealed by X-ray crystallography include a large degree of propeller twisting of adenine bases, narrowed minor grooves, and the formation of three-centered H-bonds between dA and dT bases. We report UV resonance Raman (UVRR) and CD spectroscopic studies of two related DNA dodecamer duplexes, d(CGCAAATTTGCG)(2) (A(3)T(3)) and d(CGCATATATGCG)(2) [(AT)(3)]. These studies address the presence of three-centered H-bonds in the B' conformation and gauge the impact of these putative H-bonds on the structural and thermodynamic properties of the A(3)T(3) duplex. UVRR and CD spectra reveal that the premelting transition is only observed for the A(3)T(3) duplex, is primarily localized to the dA and dT bases, and is associated with base stacking interactions. Spectroscopic changes associated with the premelting transition are not readily detectable for the sugar-phosphate backbone or the cytosine and guanosine bases. The temperature-dependent concerted frequency shifts of dA exocyclic NH(2) and dT C4=O vibrational modes suggest that the A(3)T(3) duplex forms three-centered hydrogen bonds at low temperatures, while the (AT)(3) duplex does not. The enthalpy of this H-bond, estimated from the thermally induced frequency shift of the dT C4=O vibrational mode, is approximately 1.9 kJ/mol or 0.46 kcal/mol.     

A four-way junction with triple-helical arms: design, characterization, and stability

The formation of the four-way junction containing four triple-helical arms has been demonstrated using chemical methods (polyacrylamide gel electrophoresis and chemical footprinting using OsO(4) as a probe) and physical methods (UV absorbance melting and DSC). The junction J(T1T3) was assembled from two 20-mer purine strands and two 44-mer pyrimidine strands. To determine the contribution of the different arms to the stability of the complete structure of J(T1T3), the junction was compared to two simplified substructures, J(T1) and J(T3), respectively. Common to these complexes is the underlying double-helical four-way junction Js. Addition of Na(+) had a profound effect on stabilizing and subsequently folding the junctions into the stacked X-structures. The following results support the structure present: (i) The native polyacrylamide electrophoresis exhibits only a single band(s) corresponding to one species present when all four single strands are mixed in equal amounts. (ii) OsO(4) modifications were investigated at pH 5.0 and in the presence of 10 mM Mg(2+) and 100 mM Na(+). There is no cleavage of thymine residues at the branch point and throughout the structure. (iii) The thermal unfolding of J(T1) and J(T3) illustrates that the triple-helical arms are more stable than the double-helical arms which are contained in these junctions and that J(T1T3) with four triple-helical arms is slightly more stable than J(T1) and J(T3). (iv) The calorimetric transition enthalpies determined for the arms of J(T1T3) are comparable to those associated with the unfolding of its corresponding arms in J(T1) and J(T3). The results also illustrate that the formation of the junctions is not restricted by the pH, [Na(+)], sequence composition of the arms, and/or the loop position.     

Calorimetric and spectroscopic investigation of drug-DNA interactions. I. The binding of netropsin to poly d(AT)

We report the first calorimetric investigation of netropsin binding to poly d(AT). Temperature-dependent uv absorption, circular dichroism (CD), batch calorimetry, and differential scanning calorimetry (DSC) were used to detect, monitor, and thermodynamically characterize the binding process. The following results have been obtained: 1) Netropsin groove binding is accompanied by a large exothermic enthalpy of 9.2 kcal/mol of drug bound at 25 degrees C. This indicates that a large negative binding enthalpy may be a necessary but not a sufficient criterion for drug intercalation. We suggest that the exothermic binding might be correlated with specific H-bonding interactions. 2) From the difference in DSC transition enthalpies in the presence and absence of netropsin, we calculate a binding enthalpy of -10.7 kcal/mol of netropsin at 88 degrees C. 3) We calculate a positive delta S for netropsin binding to poly d(AT) at 25 degrees C. This positive entropy change may reflect netropsin-induced release of condensed cations and/or bound water. 4) The netropsin-saturated duplex monophasically melts 46 degrees C higher than the free duplex. The unsaturated duplex melts through two thermally-resolved transitions that correspond to netropsin-free and netropsin-bound regions. These two regions interact dynamically with no substantial influence on the thermal stabilities of the separate domains. 5) Netropsin binding decreases the cooperativity of the duplex to single strand transition.     

Salt-dependent conformational transitions in the self-complementary deoxydodecanucleotide d(CGCAATTCGCG): Evidence for hairpin formation

Differential scanning calorimetry (DSC), temperature-dependent uv-absorption spectroscopy, and temperature-dependent CD were used to monitor and characterize the salt-dependent, thermally induced structural transitions in the deoxydodecanucleotide d(CGCGAATTCGCG). At the high oligomer concentrations required for DSC, the calorimetric scans revealed a single, monophasic transition curve at all salt concentrations. Based on previous nmr melting studies under similar conditions, we conclude that these monophasic transitions correspond to the cooperative duplex-to-single-strand conversion of the dodecamer. By contrast, at the lower oligomer concentrations used for the spectroscopic studies, the shapes of the uv and CD melting curves were found to depend on the concentration of the added salt. At high salt (≥0.1M Na⁺), a single, monophasic transition curve was observed. At lower salt (?0.01M Na⁺), the CD and uv melting curves exhibit biphasic behavior. Based on the concentration dependence, the enthalpy, and the cooperativity of each transition in the biphasic curve, we conclude that at low salt and low oligomer concentrations, the dodecamer melts in a sequential manner involving initial disruption of a duplex structure and subsequent disruption of a hairpin structure.     

Impact of the third-strand orientation on the thermodynamic stability of the four-way DNA junction

The physical properties of a triple-helical DNA four-way junction J(T2T4) have been characterized by means of UV spectroscopy, CD spectroscopy, and differential scanning calorimetry (DSC). J(T2T4) is another four-way junction that was designed in addition to J(T1T3) (N. Makube and H. H. Klump (2000) Arch. Biochem. Biophys. 377, 31-42) to study the effects of third strands on the stability of the four-way junction with triple-helical arms. The pH titration curves illustrate the sequential folding of single strands to double-helical four-way junctions and finally the binding of third strands to their respective W-C duplexes. CD measurements confirm triplex formation under appropriate pH and ionic strength conditions. The CD spectra also suggest different melting patterns for the triple-helical arms of J(T2T4). The melting temperature as a function of pH or ionic strength characterizes the effect of the third strands on the structural stability. Increased sodium concentration and low pH conditions enhances and stabilizes the overall structure of the junction. The results also indicate that all triplexes in J(T2T4) are formed in the absence of salt and at low pH; however, the junction may, under these conditions, assume a conformation different from the one assumed in the presence of salt. Through the deconvolution of DSC data, the calorimetric enthalpies associated with melting of arms of the junctions were determined. The loops are designed to have the same enthalpic effect on the different arms. The stabilizing effect of the loops is more pronounced when those loops are shifted from arms 1 and 3 in J(T1T3) to arms 2 and 4 in J(T2T4) without changing any of the sequences. Overall, J(T2T4) is slightly more stable than J(T1T3). The differences can be attributed to sequence effects rather than structural effects. All the results illustrate that binding of the third strand in either of the two orientations 5'5'3' (J(T2T4)) or 5'3'3' (J(T1T3)) stabilizes the underlying double-helical four-way junction and its triple-helical arms.     

A dumbbell-shaped, double-hairpin structure of DNA: a thermodynamic investigation

We report the first calorimetric and spectroscopic investigation on a member of a new class of nucleic acid secondary structures in which both ends of a duplex core are closed by single-stranded loops. Such structures can be formed intramolecularly from appropriately designed base sequences. We have synthesized the 24-mer sequence shown, and we present calorimetric, spectroscopic, and electrophoretic (formula; see text) evidence that it adopts a dumbbell-shaped, double-hairpin structure. Our data allow us to reach the following conclusions: (1) The phosphodiester gap in the center of the core duplex of the dumbbell does not reduce the transition enthalpy relative to that measured for the corresponding octameric duplex d(GGAATTCC)2. (2) Incorporation of a 5'-phosphate group into the gap decreases the thermal stability of the dumbbell relative to its unphosphorylated sequence. On the basis of the salt dependence of this effect, we propose that the phosphorylation--induced decrease in thermal stability is electrostatic in origin. From the changes in the transition enthalpy and entropy, we suggest that the phosphorylation-induced decrease in thermal stability of the double hairpin arises from electrostatically induced based unstacking at the nick. (3) The thymine residues in the loop behave both electrostatically and enthalpically like denatured single strands. Published nuclear magnetic resonance studies reveal partial stacking of thymine residues in the loops of linear hairpin structures. If this feature persists in the double-hairpin structure, then the spatial overlap of thymine residues in the loops does not necessarily produce a favorable enthalpic contribution. (4) When both ends of the nicked octameric core duplex are constrained by loops of only four thymine residues, the dumbbell structure may adopt conformations in which the 5' and 3' ends at the nick are twisted relative to the helical axis and therefore are not in phase. Such conformations would account for the observed resistance of the double-hairpin structure to ligation, since the 3'OH and 5'P would no longer be collinear.     

Influence of an exocyclic guanine adduct on the thermal stability, conformation, and melting thermodynamics of a DNA duplex.

As part of an overall program to characterize the impact of mutagenic lesions on the physiochemical properties of DNA, we report here the results of a comparative spectroscopic study on pairs of DNA duplexes both with and without an exocyclic guanine lesion. Specifically, we have studied a family of four 13-mer duplexes of the form d(CGCATGYGTACGC).d(GCGTACZCATGCG) in which Y is either the normal deoxyguanosine residue (G) or the exocyclic guanine adduct 1,N2-propanodeoxyguanosine (X), while Z is either deoxycytosine (C) or deoxyadenosine (A). Thus, the four duplexes studied, which can be designated by the identity of their central Y.Z base pair, are a Watson-Crick duplex (GC), a duplex with a central mismatch (GA), and two duplexes with exocyclic guanine lesions (X), that differ only by the base opposite the lesion (XC and XA). The data derived from our spectroscopic measurements on these four duplexes have allowed us to evaluate the influence of the exocyclic guanine lesion, as well as the base opposite the lesion, on the conformation, thermal stability, and melting energetics of the host DNA duplex. To be specific, our circular dichroism (CD) spectra show that the exocyclic guanine lesion induces alterations in the duplex structure, while our temperature-dependent optical measurements reveal that these lesion-induced structural alterations reduce the thermal stability, the transition enthalpy, and the transition free energy of the duplex.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thermodynamic, spectroscopic, and equilibrium binding studies of DNA sequence context effects in four 40 base pair deoxyoligonucleotides

Effects of different end sequences on melting, circular dichroism spectra (CD), and enzyme binding properties were investigated for four 40 base pair, non-self-complementary duplex DNA oligomers. The center sequences of these oligoduplexes have either of two 22 base pair modules flanked on both sides by sequences differing in AT content. Temperature-induced melting transitions monitored by differential scanning calorimetry (DSC) and ultraviolet absorbance were measured for the six duplexes in buffered 115 mM Na(+) solutions. Values of the melting transition enthalpy, DeltaH(cal), and entropy, DeltaS(cal), were obtained directly from DSC experiments. Melting transition parameters, DeltaH(vH) and DeltaS(vH), were also estimated from a van't Hoff analysis of optical melting curves collected as a function of DNA concentration, assuming that the melting transition is two-state. Melting free energies (20 degrees C) evaluated from DSC melting experiments on the four duplex DNAs ranged from -52.2 to -77.5 kcal/mol. Free energies based on the van't Hoff analysis were -37.9 to -58.8 kcal/mol. Although the values are different, trends in the melting free energies of the four duplex DNAs as a function of sequence were identical in both DSC and optical analyses. Subject to several assumptions, values for the initiation free energy were estimated for each duplex, defined as DeltaG(int) = DeltaG(cal) - DeltaG(pred), where DeltaG(cal) is the experimental free energy at 20 degrees C determined from the experimentially measured values of the transition enthalpy, DeltaH(cal), and entropy, DeltaS(cal). The predicted free energy of the sequence, DeltaG(pred)(20 degrees C), is obtained using published nearest-neighbor sequence stability values. For three of the four duplexes, values of DeltaG(int) are essentially nil. In contrast, the duplex with 81.8% GC has a considerably higher estimate of DeltaG(int) = 7.1 kcal/mol. The CD spectra for the six duplexes collected over the wavelength range from 200 to 320 nm are also sequence-dependent. Factor analysis of the CD spectra by singular value decomposition revealed that the experimental CD spectra could be reconstructed from linear combinations of two minor and one major subspectra. Changes in the coefficients of the major subspectrum for different sequences reflect incremental sequence-dependent variations of the CD spectra. Equilibrium binding by BamHI restriction endonuclease to the 40 base pair DNAs whose central eight base pairs contain the recognition sequence for BamHI restriction enzyme bounded by A.T base pairs, 5'-A-GGATCC-A-3' was investigated. Binding assays were performed by titering BamHI against a constant concentration of each of the duplex DNA substrates, in the absence of Mg(2+), followed by analysis by gel retardation. Under the conditions employed, the enzyme binds but does not cleave the DNAs. Results of the assays revealed two binding modes with retarded gel mobilities. Binding isotherms for the fraction of bound DNA species versus enzyme concentration for each binding mode were constructed and analyzed with a simple two-step equilibrium binding model. This analysis provided semiquantitative estimates on the equilibrium binding constants for BamHI to the four DNAs. Values obtained for the binding constants varied only 7-fold and ranged from 6 x 10(-)(8) to 42 x 10(-)(8) M, with binding free energies from -8.6 to -9.7 (+/- 0.2) kcal/mol depending on the sequence that flanks the enzyme binding site. Unlike what was found earlier in binding studies of the 22 base pair duplexes that constitute the core modules of the present 40-mers [Riccelli, P. V., Vallone, P. M., Kashin, I., Faldasz, B. D., Lane, M. J., and Benight, A. S. (1999) Biochemistry 38, 11197-11208], no obvious relationship between binding and stability was found for these longer DNAs. Apparently, effects of flanking sequence stability on restriction enzyme binding may only be measurable in very short duplex deoxyoligonucl     

Thermodynamic and computational studies of DNA triple helices containing a nucleotide or a non-nucleotide linker in the third strand.

In this paper we report a thermodynamic characterisation of stability and melting behaviour of four different triple helices at pH 6.0. The target duplex consists of 16 base pairs in alternate sequence of the type 5'-(purine)(m)(pyrimidine)(m)-3'. The four triplexes are formed by targeting the 16-mer duplex with an all pyrimidine 16-mer or 15-mer or 14-mer third strand. The 16-mer oligonucleotide contains a 3'-3' phosphodiester junction and corresponding triplex was named 16-mer P. The 14-mer oligonucleotide contains a non-nucleotide linker, the 1,2,3 propanetriol residue and the corresponding triplex was named 14-mer PT. For the 15-mer oligonucleotide both junctions were alternatively used and the relative triplexes were named 15-mer P and 15-mer PT, respectively. These linkers introduce the appropriate polarity inversion and let the third strand switch from one oligopurine strand of the duplex to the other. Thermal denaturation profiles indicate the initial loss of the third strand followed by the dissociation of the target duplex. Transition enthalpies, entropies and free energies were derived from differential scanning calorimetric measurements. The comparison of Gibbs energies reveals that a more stable triplex is obtained when in the third strand there is the lack of one nucleotide in the junction region and a propanetriol residue as linker was used. The thermodynamic data were discussed in light of molecular mechanics and dynamics calculations.     

Modeling protein density of states: additive hydrophobic effects are insufficient for calorimetric two-state cooperativity

A well-established experimental criterion for two-state thermodynamic cooperativity in protein folding is that the van't Hoff enthalpy DeltaH(vH) around the transition midpoint is equal, or very nearly so, to the calorimetric enthalpy DeltaH(cal) of the entire transition. This condition is satisfied by many small proteins. We use simple lattice models to provide a statistical mechanical framework to elucidate how this calorimetric two-state picture may be reconciled with the hierarchical multistate scenario emerging from recent hydrogen exchange experiments. We investigate the feasibility of using inverse Laplace transforms to recover the underlying density of states (i.e., enthalpy distribution) from calorimetric data. We find that the constraint imposed by DeltaH(vH)/DeltaH(cal) approximately 1 on densities of states of proteins is often more stringent than other "two-state" criteria proposed in recent theoretical studies. In conjunction with reasonable assumptions, the calorimetric two-state condition implies a narrow distribution of denatured-state enthalpies relative to the overall enthalpy difference between the native and the denatured conformations. This requirement does not always correlate with simple definitions of "sharpness" of a transition and has important ramifications for theoretical modeling. We find that protein models that assume capillarity cooperativity can exhibit overall calorimetric two-state-like behaviors. However, common heteropolymer models based on additive hydrophobic-like interactions, including highly specific two-dimensional Gō models, fail to produce proteinlike DeltaH(vH)/DeltaH(cal) approximately 1. A simple model is constructed to illustrate a proposed scenario in which physically plausible local and nonlocal cooperative terms, which mimic helical cooperativity and environment-dependent hydrogen bonding strength, can lead to thermodynamic behaviors closer to experiment. Our results suggest that proteinlike thermodynamic cooperativity may require a cooperative interplay between local and nonlocal interactions. The prospect of using calorimetric data to constrain Z-scores of knowledge-based potentials is discussed.     

Construction of a synthetic Holliday junction analog and characterization of its interaction with a Saccharomyces cerevisiae endonuclease that cleaves Holliday junctions

We describe the construction and characterization of an oligonucleotide Holliday junction analog and characterize its interaction with a Saccharomyces cerevisiae endonuclease that cleaves Holliday junctions. A Holliday junction analog containing four duplex arms and 54 base pairs was constructed by annealing four unique synthetic oligonucleotides. Mixing curve analysis showed that the complex contained a 1:1:1:1 mol ratio of the four unique sequence strands. In addition, a linear duplex with a sequence identical to two of the junction arms was also constructed for use as a control fragment. High resolution gel exclusion chromatography was used to purify and characterize the synthetic junction. The synthetic Holliday junction was found to be a specific inhibitor of a S. cerevisiae enzyme that catalyzes the cleavage of Holliday junctions. Under standard cleavage conditions, 50% inhibition was observed at a synthetic Holliday junction to substrate ratio of 7/1, whereas no inhibition by linear duplex was observed at molar ratios in excess of 150/1. Kinetic analysis showed that Holliday junction was a competitive inhibitor of the reaction and had an apparent Ki = 2.5 nM, although the mode of inhibition was complex. The synthetic Holliday junction was not a substrate for the enzyme, but was found to form a specific complex with the enzyme as evidenced by polyacrylamide gel electrophoresis DNA binding assays.     

NMR analysis of DNA junctions: imino proton NMR studies of individual arms and intact junction

The NMR resonances from the hydrogen-bonded guanine and thymine imino protons of base pairs in the four separate complexes forming the arms of a stable DNA four-arm junction have been assigned by using sequential nuclear Overhauser effects connecting protons in adjacent pairs. Comparison of the spectra of these individual duplex arms with that of the intact four-stranded junction suggests that base pairing occurs at the site of branching. The presence of new resonances in the spectrum of the junction can be inferred from comparison of the junction spectrum with the simulated spectra of the four individual arms. In addition, upfield shifts of the ring protons in the base pairs at the penultimate positions in the complex are observed, consistent with a change in the structure at the site of branching. These studies represent the first stage of a detailed analysis of the structure and dynamics of a DNA junction.     

Calorimetric and spectroscopic investigation of drug--DNA interactions: II. Dipyrandium binding to poly d(AT).

We report the first calorimetric investigation of steroid diamine binding to a DNA duplex. Absorption spectroscopy, batch calorimetry, and differential scanning calorimetry (DSC) have been used to detect, monitor, and thermodynamically characterize the binding of the steroid diamine, dipyrandium, to poly d(AT). The following thermodynamic data for the binding in 16 mM Na+ at 25 degrees C have been obtained: delta G degree = -6.5 kcal/mol, delta H degree = +4.2 kcal/mol, and delta S = +36 e.u. We interpret the endothermic binding enthalpy in terms of steroid-induced conformational changes in the duplex (e.g. "kinking"). The large positive entropy is interpreted in terms of binding-induced release of bound water and condensed sodium ions. The salt-dependence of the binding constant is interpreted in terms of dipyrandium site-binding involving only one of the two charged ends of the steroid. The optical and DSC curves for the unsaturated steroid-poly d(AT) complexes exhibit biphasic behavior. A comparison of the van't Hoff and the calorimetric transition enthalpies reveals that steroid binding reduces the cooperativity of the transition.     

Simultaneous modeling of phase and calorimetric behavior in an amphiphilic peptide/phospholipid model membrane

Differential scanning calorimetry (DSC) experiments have been performed on the amphiphilic peptide/1,2-bis(perdeuteriopalmitoyl)-sn-glycero-3-phosphocholine system for which partial phase diagrams have been measured by deuterium nuclear magnetic resonance. The solute concentration dependence of the transition enthalpy in such systems is often interpreted in terms of an annulus of lipid withdrawn, by the solvent, from participation in the transition while the bulk lipid melts with its fully enthalpy. This idea is equivalent to postulating ideal mixing between the lipid and the peptide/lipid complex, and there is little justification for such an assumption. Adaptation of regular solution theory to this system demonstrates that the peptide concentration dependence of the transition enthalpies can be incorporated into a thermodynamic model which reproduces the observed phase behavior fairly well without postulating that a complexing annulus of lipid around the peptide be withdrawn from participating in the chain-melting transition. The model parameters determined by simultaneous fitting of the phase behavior and transition enthalpies are used to simulate the DSC scan shapes. The asymmetry of the calorimetric scans for chi 2 less than or equal to 0.02 is reproduced by the model, but a broad component observed for higher concentration is not. In light of the results presented here, previous analyses of the calorimetric behavior of two-component systems in terms of symmetric transitions which do not account for the possible extent of a region of two-phase equilibrium must be questioned.     

Conformational changes in single-strand DNA as a function of temperature by SANS

Small-angle neutron scattering (SANS) measurements were performed on a solution of single-strand DNA, 5'-ATGCTGATGC-3', in sodium phosphate buffer solution at 10 degrees C temperature increments from 25 degrees C to 80 degrees C. Cylindrical, helical, and random coil shape models were fitted to the SANS measurements at each temperature. All the shapes exhibited an expansion in the diameter direction causing a slightly shortened pitch from 25 degrees C to 43 degrees C, an expansion in the pitch direction with a slight decrease in the diameter from 43 degrees C to 53 degrees C, and finally a dramatic increase in the pitch and diameter from 53 degrees C to 80 degrees C. Differential scanning calorimeter scans of the sequence in solution exhibited a reversible two-state transition profile with a transition temperature of 47.5 +/- 0.5 degrees C, the midpoint of the conformational changes observed in the SANS measurements, and a calorimetric transition enthalpy of 60 +/- 3 kJ mol(-1) that indicates a broad transition as is observed in the SANS measurements. A transition temperature of 47 +/- 1 degrees C was also obtained from ultraviolet optical density measurements of strand melting scans of the single-strand DNA. This transition corresponds to unstacking of the bases of the sequence and is responsible for the thermodynamic discrepancy between its binding stability to its complementary sequence determined directly at ambient temperatures and determined from extrapolated values of the melting of the duplex at high temperature.     

Hairpin Formation of d(CGCG-TA-CGCG), d(CGCG-TG-CGCG) and Their Cytosine Methylated Analogs

Abstract

Hairpin formations of decamers d(CGCG-TA-CGCG), d(CGCG-TG-CGCG), and their m⁵dC analogs are evidenced by the existence of biphasic absorbance melting profiles in which the lower transition temperature increases with increasing oligomer concentration, whereas the higher melting temperature is concentration independent. The corresponding temperature dependent CD intensity at 285 nm exhibits a maximum around 55°C. These observations are consistent with the interpretation that the lower temperature transition corresponds to the duplex to hairpin transformation while the melting of hairpins into single strands constitutes the higher temperature transition. The CD spectrum of the hairpin conformation appears to be characterized by a couplet with nearly equal positive and negative intensities at 285 and 255 nm, respectively, while a significantly smaller intensity at 285 nm is apparent for the duplex form. The hairpin conformation is suspected to contain a two-nucleotide loop. Titrations with NaCl further suggest that, in contrast to the TA sequence, the TG sequence with wobble base pairing favors Z formation under high salt conditions.     

Hairpin formation of d(CGCG-TA-CGCG), d(CGCG-TG-CGCG) and their cytosine methylated analogs

Hairpin formations of decamers d(CGCG-TA-CGCG), d(CGCG-TG-CGCG), and their m5dC analogs are evidenced by the existence of biphasic absorbance melting profiles in which the lower transition temperature increases with increasing oligomer concentration, whereas the higher melting temperature is concentration independent. The corresponding temperature dependent CD intensity at 285 nm exhibits a maximum around 55 degrees C. These observations are consistent with the interpretation that the lower temperature transition corresponds to the duplex to hairpin transformation while the melting of hairpins into single strands constitutes the higher temperature transition. The CD spectrum of the hairpin conformation appears to be characterized by a couplet with nearly equal positive and negative intensities at 285 and 255 nm, respectively, while a significantly smaller intensity at 285 nm is apparent for the duplex form. The hairpin conformation is suspected to contain a two-nucleotide loop. Titrations with NaCl further suggest that, in contrast to the TA sequence, the TG sequence with wobble base pairing favors Z formation under high salt conditions.